Calculation for Electric Dipole Moments of Lepton and Neutron in the N-B-LSSM via the Mass Insertion Approximation

TL;DR

This paper calculates the electric dipole moments of leptons and neutrons in the N-B-LSSM using the Mass Insertion Approximation, revealing their dependence on model parameters and consistency with experimental limits.

Contribution

It provides the first one-loop analytical expressions for EDMs in the N-B-LSSM and explores their parameter dependence and experimental viability.

Findings

EDMs depend on specific model parameters like $g_{YB}$ and $ aneta$

Numerical results satisfy current experimental bounds

Offers a systematic approach for CP violation studies in N-B-LSSM

Abstract

In the N-B-LSSM, we calculate the electric dipole moments (EDMs) of lepton and neutron at the one loop level via the Mass Insertion Approximation (MIA). In the Standard Model (SM), charge parity (CP) violation originates only from the single phase of the Cabibbo-Kobayashi-Maskawa (CKM) matrix, and the predicted EDMs of lepton and neutron are far below the current experimental upper limits. Thus, EDMs serve as sensitive probes for exploring CP-violating phases in new physics. The N-B-LSSM extends the Minimal Supersymmetric Standard Model (MSSM) by introducing right-handed neutrino superfields and additional singlet Higgs superfields, which enriches the particle spectrum and the sources of CP violation. We derive the one loop analytical expressions for lepton and quark EDMs, and reveal their dependence on model parameters such as $g_{YB}$, $\theta_{\mu_H}$, $\theta_{1'}$, $\theta_{BB'}$ and $\tan\beta$. Numerical analyses demonstrate that within a reasonable parameter space, the EDMs of leptons (electron, muon, tau) and the neutron can satisfy the current experimental limitations. This study provides a systematic theoretical tool and numerical reference for exploring CP violation and new physics under the N-B-LSSM.